ES2790575T3 - Compressor overload protection control method and apparatus - Google Patents

Abstract

A compressor overload protection control method, wherein the compressor overload protection control method is configured for overload protection of a dehumidifier and an air conditioner, and each of the dehumidifier and the air conditioner comprises an evaporator and the compressor, the compressor overload protection control method comprising: detecting (S101) whether the compressor is in the on state or off state by detecting the tube temperature of an evaporator; judging (S102) that the compressor is under overload protection when the compressor is in the off state and judging that the compressor is not under overload protection when the compressor is in the on state; and protect (S103) the fluorine shortage protection if the compressor is under the overload protection.

Description

DESCRIPTION

Compressor overload protection control method and apparatus

Technical field of the invention

The invention relates to the field of control, and in particular, to a compressor overload protection control method and apparatus.

Background of the invention

To ensure the safe operation of a dehumidifier and an air conditioner, in the relevant art, the dehumidifier and the air conditioner will have a refrigerant leak protection function and a general overload protection function. The overload protection function is mainly performed by an overload protector.

For example, when the overload protector detects that the dehumidifier and air conditioner exhaust temperatures exceed the exhaust temperature threshold values, the dehumidifier and air conditioner compressor power switches will turn off, so that dehumidifier and air conditioner overload protection is performed. At that time, even though the dehumidifier and air conditioner compressor power switches have been turned off, the compressors are generally still electrified. Therefore, when a data parameter detected by a main controller satisfies the judgment logic for refrigerant leakage protection, the dehumidifier and air conditioner will issue a fluorine shortage alarm and execute a fluorine shortage protection move. fluorine. Under the circumstances, the dehumidifier and air conditioner confuse overload protection with fluoride shortage protection, thus triggering a false fluorine shortage alarm. CN-101929719-B provides a related technical solution; however, the aforementioned problem remains unsolved.

Currently no effective solution to the problem has been proposed in the relevant art that the fluorine shortage false alarm is easily triggered.

Summary of the invention

The invention has as its main objective to provide a compressor overload protection control method and apparatus, which are intended to solve the problem in the relevant art that the false fluorine shortage alarm is easily activated.

To achieve the objective, in accordance with one aspect of the invention, a compressor overload protection control method is provided, which may include: the status of a compressor is detected; it is judged whether the compressor is under overload protection; And if the compressor is under the overload protection, the fluorine shortage protection is protected.

Also, the compressor overload protection control method can be configured to protect a dehumidifier against overload. The dehumidifier may include an evaporator and the compressor. The stage in which the compressor status is detected may include: an evaporator tube temperature is detected within a first target time period and an ambient temperature and an evaporator tube temperature within a second target time period, the first target time period and the second target time period being successive time periods, and the second target time period being subsequent to the first target time period. The stage in which it is judged whether the compressor is under overload protection may include that: it is judged whether the tube temperature within the first target time period is continuously increasing and reaching a maximum value; After judging that the tube temperature within the first target time period is continuously increasing and reaches the maximum value, it is judged whether a temperature difference obtained by the continuous increase in tube temperature within the first target time period is greater or same as a preset temperature difference; After judging that the temperature difference obtained by the continuous increase in tube temperature within the first target time period is greater than or equal to the preset temperature difference, it is judged whether a difference between the ambient temperature and the tube temperature within the second target time period it is less than a preset temperature difference limit value; and if the difference between the ambient temperature and the tube temperature within the second target time period is considered to be less than the preset temperature difference limit value, it is determined that the compressor is under the overload protection. Also, the step in which the evaporator tube temperature is detected within the first target time period may include that: a first evaporator tube temperature is detected at first, a second evaporator tube temperature is detected in a second moment, and a third temperature of the evaporator tube is detected in a third moment, being the first moment, the second moment and the third moment successive time points within the first target time period, the second moment being after the first moment, and the third moment being after the second moment. The stage in which it is judged whether the tube temperature within the first target time period is continuously increasing and reaches the maximum value may include that: it is judged whether the evaporator tube temperature within the first target time period is continuously increasing and reaches the maximum value judging a size relationship between the first tube temperature, the second tube temperature and the third tube temperature.

Also, the stage in which the evaporator tube temperature is detected within the second target time period may include that: a fourth evaporator tube temperature is detected in a fourth time, and a fifth evaporator tube temperature is detected in a fifth moment, the fourth moment and the fifth moment being successive time points within the second objective time period, and the fifth moment being after the fourth moment. The stage in which it is judged whether the difference between the ambient temperature and the tube temperature within the second target time period is less than the preset temperature difference limit value may include that: a temperature difference is calculated between the fifth temperature the tube and the fourth tube temperature; and it is judged whether the tube temperature falls continuously within the second target time period by judging whether the temperature difference is less than 0.

Likewise, the stage in which the protection against the shortage of fluorine is protected may include that: a preset period of protection against overload is obtained; the first target time period and the second target time period being removed from the preset overload protection time period to determine a third target time period, the third target time period being successive to the second target time period and the third being target time period after the second target time period; and the protection against fluoride shortage is protected within the third target time period.

Also, before the fluoride shortage protection is protected within the third target time period, the stage in which the fluoride shortage protection is protected may further include: a protection stop command is obtained against the shortage of fluorine sent to the compressor, including the fluorine shortage protection stop command a first fluorine shortage protection stop command, a second fluorine shortage protection stop command and a third stop command protection against fluoride shortage; and it is detected whether a time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, when it is detected that the time when the third fluorine shortage protection stop command is sent is not within the first target time period or the second target time period, the fluorine shortage protection is protected.

To achieve the objective, according to another aspect of the invention, a compressor overload protection control apparatus is provided, which may include: a detection unit, configured to detect the state of a compressor; a judgment unit, configured to judge whether the compressor is under overload protection; and a protection unit, configured to protect protection against fluorine shortage if the compressor is under overload protection.

Also, the compressor overload protection control apparatus can be configured for overload protection of a dehumidifier. The dehumidifier may include an evaporator and the compressor. The sensing unit may further be configured to detect an evaporator tube temperature within a first target time period and an ambient temperature and an evaporator tube temperature within a second target time period, the first time period being target and the second target time period successive time periods, and the second target time period being after the first target time period. The judgment unit may include: a first judgment module, configured to judge whether the tube temperature within the first target time period is continually increasing and reaching a maximum value; a second judgment module, configured to judge whether a temperature difference obtained by continuously increasing the tube temperature within the first target time period is greater than or equal to a preset temperature difference after the temperature of the tube is judged tube within the first target time period continuously increases and reaches the maximum value; a third judgment module, configured to judge whether a difference between the ambient temperature and the tube temperature within the second target time period is less than a preset temperature difference limit value after the temperature difference obtained is judged by the continuous increase in the temperature of the tube within the first the target time period is greater than or equal to the preset temperature difference; and a first determination module, configured to determine that the compressor is under overload protection if the difference between ambient temperature and tube temperature within the second target time period is considered to be less than the difference limit value of preset temperature.

Also, the detection unit may include: a first detection module, configured to detect a first temperature of the evaporator tube at first; a second detection module, configured to detect a second temperature of the evaporator tube in a second moment; and a third module of detection, configured to detect a third evaporator tube temperature at a third time, the first time, the second time and the third time being successive time points within the first target time period, the second time being after the first time, and being the third moment after the second moment. The first evaluation module can be further configured to judge whether the evaporator tube temperature within the first target time period continuously increases and reaches the maximum value by judging a size relationship between the first tube temperature, the second tube temperature, and the third tube temperature.

Likewise, the detection unit may further include: a fourth detection module, configured to detect a fourth temperature of the evaporator tube in a fourth time; and a fifth detection module, configured to detect a fifth temperature of the evaporator tube at a fifth moment, the fourth moment and the fifth moment being successive time points within the second target time period, and the fifth moment being after the fourth moment. The second judgment module may include: a calculation sub-module, configured to calculate a temperature difference between the fifth tube temperature and the fourth tube temperature; and a judgment sub-module, configured to judge whether the tube temperature continuously falls within the second target time period by judging whether the temperature difference is less than 0.

Likewise, the protection unit may include: a first obtaining module, configured to obtain a preset overload protection time period; a second determination module, configured to remove the first target time period and the second target time period from the preset overload protection time period to determine a third target time period, the third target time period being successive to the second target time period and being the third target time period after the second target time period; and a protection module, configured to protect the protection against fluorine shortage within the third target time period.

Likewise, the protection unit can also include: a second obtaining module, configured to obtain a stop command for protection against low fluoride sent to the compressor before protection against low fluoride is protected within the third period of target time, including the fluorine shortage protection stop command, a first fluorine shortage protection stop command, a second fluorine shortage protection stop command, and a third shortage protection stop command of fluorine; and a sixth detection module, configured to detect whether a time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, in which The protection unit can be further configured to protect the fluorine shortage protection when it is detected that the time when the third fluorine shortage protection stop command is sent is not within the first target time period or the second target time period.

By means of the invention, the condition of the compressor is detected; it is judged whether the compressor is under overload protection; and if the compressor is under the overload protection, the fluorine shortage protection is protected. The problem in the relevant art that the fluorine shortage false alarm is easily activated is solved, thus achieving the effect of avoiding the fluorine shortage false alarm when the compressor is under the overload protection.

Brief description of the drawings

The drawings described herein are intended to provide a further understanding of the invention and form part of the invention. The schematic embodiments and descriptions of the invention are intended to explain the invention, and do not form inappropriate limits to the invention. In the drawings:

Figure 1 is a diagram of a compressor overload protection control apparatus according to a first embodiment of the invention;

Figure 2 is a diagram of a compressor overload protection control apparatus according to a second embodiment of the invention;

Figure 3 is a diagram of a curve with respect to ambient temperature and tube temperature of an evaporator during compressor overload protection according to a second embodiment of the invention;

Figure 4 is a flow chart of a compressor overload protection control method according to a first embodiment of the invention; Y

Figure 5 is a flow chart of a compressor overload protection control method according to a second embodiment of the invention.

Detailed description of the realizations

It is important to note that the embodiments of the invention and the features in the embodiments can be combined under the condition that there are no conflicts. The invention is described below with reference to the drawings and embodiments in detail.

It is important to note that a compressor overload protection control method and apparatus in the invention can be configured for overload protection of a dehumidifier and an air conditioner, wherein the dehumidifier and the air conditioner each include a compressor and an evaporator. According to embodiments of the invention, a compressor overload protection control apparatus is provided, which is configured to protect protection against fluorine shortage when a compressor is under overload protection.

Figure 1 is a diagram of a compressor overload protection control apparatus according to a first embodiment of the invention. As shown in Figure 1, the apparatus includes: a detection unit 10, a judgment unit 20 and a protection unit 30.

The detection unit 10 is configured to detect the state of a compressor. The compressor state can be an on state and an off state. It is important to note that in the embodiment of the invention, when the compressor is off, the overall compressor is still in an electrified state. When the compressor is overloaded, the compressor exhaust temperature will be very high. Once the compressor exhaust temperature is too high, the compressor will shut down. At that time, the detection unit 10 will detect that the state of the compressor is the off state. Otherwise, the detection unit 10 will detect that the compressor status is the on status. The sensing unit 10 can detect whether the compressor is in the on or off state by sensing the tube temperature of an evaporator. It is important to note that the detection unit 10 is part of a main controller for the dehumidifier and the air conditioner.

The evaluation unit 20 is configured to judge whether the compressor is under overload protection. When the detection unit 10 detects that the state of the compressor is the off state by detecting the temperature of the evaporator tube, the judgment unit 20 can judge that the compressor is under the overload protection. Otherwise, when the detection unit 10 detects that the compressor state is the on state by detecting the temperature of the evaporator tube, the judgment unit 20 can judge that the compressor is not under the overload protection, specifically , the compressor is in a normal operating state.

The protection unit 30 is configured to protect protection against fluorine shortage if the compressor is under overload protection. When the judgment unit 20 judges that the compressor is under the overload protection, the protection unit 30 is configured to protect the protection against fluorine shortage. Otherwise, the protection unit 30 does not protect the protection against the shortage of fluorine, in which protecting the protection against the shortage of fluorine by the protection unit 30 may be a control logic to protect the protection against the shortage of fluorine.

By carrying out the invention, when the detection unit 10 detects that the compressor exhaust temperature is too high, it is determined that the compressor is off. When the compressor is off, the judgment unit 20 judges that the compressor is under the overload protection, and at this time, the protection unit 30 executes a protection movement of the protection against fluorine shortage. Therefore, the effect of avoiding a false fluorine shortage alarm is achieved when the compressor is under the overload protection.

Figure 2 is a diagram of a compressor overload protection control apparatus according to a second embodiment of the invention. The embodiment can be taken as a preferred mode of implementation of the embodiment shown in Figure 1. The compressor overload protection control apparatus in the embodiment includes a detection unit 10, a judgment unit 20 and a protection unit 30 in the first embodiment, wherein the judgment unit 20 includes: a first judgment module 201, a second judgment module 202, a third judgment module 203, and a first determination module 204.

The protection unit 30 here is identical to that of the first embodiment in function, and is no longer described in detail here.

The detection unit 10 is further configured to detect an evaporator tube temperature within a first target time period and an ambient temperature and an evaporator tube temperature within a second target time period, the first time period being target and the second target time period successive time periods, and the second target time period being after the first target time period.

In the embodiment of the invention, the detection unit 10 may include a first detection module, a second detection module, and a third detection module. Specifically, the first sensing module is configured to detect a first evaporator tube temperature at first; The second sensing module is configured to detect a second evaporator tube temperature at a second moment; and the third detection module is configured to detect a third temperature of the evaporator tube at a third time, in which the first time, the second time and the third time can be three successive time points within the first target time period. , and the first moment, the second moment and the third moment are arranged on a time axis according to a time sequence.

Detection unit 10 may further include a fourth detection module and a fifth detection module. Specifically, the fourth detection module is configured to detect a fourth evaporator tube temperature in a fourth time; and the fifth detection module is configured to detect a fifth temperature of the evaporator tube at a fifth time, where the fourth time and the fifth time are successive time points within the second target time period, and the fifth time is after the fourth moment.

The first evaluation module 201 is configured to judge whether the evaporator tube temperature within the first target time period is continuously increasing and reaching a maximum value. A time period of the first target time period can be preset. Preferably, the duration of the first target time period can be preset as 3 min. Within the first target time period, when the first tube temperature, the second tube temperature, and the third tube temperature increase sequentially and the three tube temperatures are successive values, the first judgment module 201 judges that the tube temperature evaporator within the first target time period increases continuously. Likewise, under a critical state, when the first tube temperature and the third tube temperature are smaller than the second tube temperature, the first judgment module 201 judges that the tube temperature within the first target time period increases. continuously and reaches the maximum value under the critical state. It is important to note that the second tube temperature corresponding to the second moment is a maximum temperature within the first target time period under the critical state.

The second evaluation module 202 is configured to judge whether a temperature difference obtained by continuously increasing tube temperature within the first target time period is greater than or equal to a preset temperature difference after the first evaluation module 201 judge that the evaporator tube temperature within the first target time period increases continuously and reaches the maximum value. For example, the preset temperature difference can be 15 degree C.

In the embodiment of the invention, the second evaluation module 202 may include a calculation sub-module and an evaluation sub-module. When the fourth detection module detects the fourth tube temperature and the fifth detection module detects the fifth tube temperature, the calculation sub-module is configured to calculate a temperature difference between the fifth tube temperature and the fourth tube temperature; and within the second target time period, when the fourth tube temperature is greater than the fifth tube temperature, that is, when the temperature difference is less than 0 and the temperatures of the two tubes are successive values, the submodule of judgment judges that the evaporator tube temperature within the second target time period drops continuously.

The third evaluation module 203 is configured to judge whether a difference between the ambient temperature and the evaporator tube temperature within the second target time period is less than a preset temperature difference limit value after the second evaluation module 202 judge that the temperature difference obtained by continuously increasing the evaporator tube temperature within the first target time period is greater than or equal to the preset temperature difference. For example, the preset temperature difference limit value can be 5 GRAD C.

In the embodiment of the invention, the first determination module 204 is configured to determine that the compressor is under overload protection after the third evaluation module 203 judges that the difference between the ambient temperature and the evaporator tube temperature within the second target time period is less than the preset temperature difference limit value. In particular, the judgment unit 20 is configured to judge that the compressor is off at this time.

In the embodiment of the invention, the protection unit 30 may include a first obtaining module, a second determining module, and a protection module. The first obtain module is configured to obtain a preset overload protection time period. For example, the preset overload protection time period can be set as 60 min. After the obtaining module obtains the preset overload protection time period, the second determining module is configured to remove the first target time period and the second target time period from the preset overload protection period to determine a third target time period, in which the first target time period, the second target time period, and the third target time period are successive time periods, and the third target time period is behind the second target time period . After obtaining the third target time period, the protection module is configured to protect the protection against fluorine shortage within the third target time period. Also, the protection module is further configured to protect the fluorine shortage protection within a time period extending backward from the third target time period. For example, Suppose the preset overload protection time period is 60 min and the durations of the first target time period and the second target time period are 3 min and 5 min, the third target time period is the last 52 min of a certain time. Therefore, the protection module can be configured to protect protection against fluorine shortage within the last 52 min of the set time or to protect protection against fluorine shortage between the last 52 min of the set time and the first 10 min of the next hour.

In the embodiment of the invention, the protection unit 30 may include a second acquisition module, a sixth detection module, and a protection unit. The second obtaining module is configured to obtain a fluorine shortage protection stop command sent to the compressor, where the fluorine shortage protection stop command includes a first fluorine shortage protection stop command , a second fluorine shortage protection stop command and a third fluorine shortage protection stop command. Specifically, when fluorine shortage protection data is detected for the first time, the main controller sends the first fluorine shortage protection stop command to the compressor; When the fluorine shortage protection data is detected a second time, the main controller sends the second fluorine shortage protection stop command to the compressor; and when the fluorine shortage protection data is detected for the third time, the main controller sends the third fluorine shortage protection stop command to the compressor. The sixth detection module is configured to detect whether a time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period. The protection unit is configured to protect the fluorine shortage protection when the sixth detection module detects that the time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, and otherwise the protection unit will not protect the protection against fluorine shortage. When the sixth detection module detects that the time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, the protection unit does not protect the protection against fluoride shortage. At that time, the fluorine shortage protection is determined to be the normal fluoride shortage protection, and a fluoride shortage protection alarm is issued.

For example, as shown in Figure 3, a horizontal axis represents a time axis (unit: min), a longitudinal axis represents a temperature axis (unit: GRAD C), a dotted line represents room temperature, and a line dashed represents the temperature of the evaporator tube. Suppose the ambient temperature is 25 DEG C, a relative ambient humidity is 80%, a maximum duration of the first target time period is 3 min, a maximum duration of the second target time period is 5 min, the difference preset temperature is 15 DEG C, and the limit value of the preset temperature difference is 5 DEG C. In the embodiment, the evaporator tube temperature within about 0 min to 10.5 min against a point A probably rises from 7 GRAD C to 14 GRAD C, and the rate of increase of the tube temperature is relatively low. The evaporator tube temperature, sensed by detection unit 10, within approximately 10.5 min to 12.5 min between point A and point B will likely continue to increase from 14 DEG C to 29 DEG C. The temperature of the evaporator evaporator tube, detected by the detection unit 10, at point B reaches a maximum value, that is, 29 GRAD C. A duration of a period of time between point A and point B is approximately 2 min, in Specifically, the time period between point A and point B can be the first target time period. After the temperature of the evaporator tube, detected by the detection unit 10, it will probably continue to increase from 14 GRAD C to 29 GRAD C, the first judgment module 201 judges that the temperature of the evaporator tube increases continuously and reaches the maximum value , that is, 29 GRAD C. The second judgment module 202 judges that a temperature difference obtained by the continuous increase in the temperature of the evaporator tube within the time period between point A and point B is 15 GRAD C, and the temperature difference, that is, 15 DEG C, is equal to the preset temperature difference, that is, 15 DEG C. Within approximately 12.5 min to 14.5 min between point B and a point C, the temperature of the evaporator tube, detected by the detection unit 10, probably ranges between 26 DEG C and 29 DEG C, and the detection unit 10 detects that the ambient temperature is 25 DEG C at the same time. Therefore, within approximately 12.5 min to 14.5 min between point B and point C, a maximum value of the difference between ambient temperature and the evaporator tube temperature is 4 GRAD C, and a value The minimum value is 1 GRAD C. Consequently, the third judgment module 203 judges that the maximum value of the difference between the ambient temperature and the evaporator tube temperature is 4 GRAD C, which is less than the limit value of difference preset temperature, that is, 5 GRAD C. By means of a detection result, the first determining module 204 of the evaluation unit 20 determines that the compressor is in an overload protection state, that is, the compressor is switched off. has stopped due to overload protection. After the first determining module 204 of the judgment unit 20 determines that the compressor is in the overload protection state, that is, the compressor has stopped due to overload protection, the protection unit 30 protects the protection against fluorine shortage from the moment, that is, 14.5 min corresponding to point C. Suppose the preset compressor overload protection time duration is 60 min, protection protection against fluorine shortage You can continue from 14.5 min to 60 min or 70 min. The protection of the protection against fluorine shortage is released 60 min or 70 min later.

Therefore, by means of the embodiments of the invention, after judging that the temperature of the evaporator tube within the first target time period increases continuously and reaches the maximum value, it is considered that the temperature difference obtained by the continuous increase of the evaporator tube temperature within the first target time period is greater than or equal to the preset temperature difference and the difference between the room temperature and the evaporator tube temperature within the second target time period is considered to be less than the preset temperature difference limit value, the protection against fluorine shortage is protected in time, and a false fluorine shortage alarm is eliminated, thus achieving the effect of avoiding false fluorine shortage alarm when the compressor is under the overload protection.

According to embodiments of the invention, a compressor overload protection control method is provided, which is configured to protect protection against fluorine shortage when a compressor is under overload protection. It is important to note that the compressor overload protection control method provided by embodiments of the invention can be executed on a computing device. It is important to note that the compressor overload protection control method provided by embodiments of the invention can be executed by means of the compressor overload protection control apparatus according to embodiments of the invention. The compressor overload protection control apparatus according to embodiments of the invention can also be configured to execute the compressor overload protection control method according to embodiments of the invention.

Figure 4 is a flow chart of a compressor overload protection control method according to a first embodiment of the invention. As shown in Figure 4, the compressor overload protection control method includes steps S101 to S103 as follows.

Step S101: The state of a compressor is detected.

Detecting the compressor state can refer to detecting whether the compressor state is an on state and an off state. It is important to note that in the embodiment of the invention, when the compressor is off, the overall compressor is still in an electrified state. When the compressor is overloaded, the compressor exhaust temperature will be very high. Once the compressor exhaust temperature is too high, the compressor will shut down. At that time, detecting the compressor state will refer to detecting that the compressor state is the off state. Otherwise, the compressor status will be detected as the on status. Compressor state detection may refer to detecting whether the compressor is in the on state or off state by detecting an evaporator tube temperature. It is important to note that step S101 is executed by a main controller for a dehumidifier and an air conditioner.

Step S102: It is judged whether the compressor is under overload protection.

When it is detected that the compressor state is the off state, it can be judged that the compressor is under the overload protection. Otherwise, when it is detected that the compressor state is the on state, it can be judged that the compressor is not under the overload protection, specifically, the compressor is in a normal operating state. When it is judged that the compressor is not under the overload protection, Step S101 is executed. When the compressor is judged to be under the overload protection, Step S103 is executed.

Step S103: Protection against fluorine shortage is protected.

When the compressor is judged to be under the overload protection, the fluorine shortage protection is protected. Otherwise, the protection against fluorine shortage is not protected, in which the protection of the protection against the fluorine shortage can be a control logic to protect the protection against the fluorine shortage.

By carrying out the invention, when it is detected that the compressor is off due to too high exhaust temperature, the compressor is considered to be under the overload protection, and at this time, the fluorine shortage protection is protected. Therefore, the effect of avoiding a false fluorine shortage alarm is achieved when the compressor is under the overload protection.

Figure 5 is a flow chart of a compressor overload protection control method according to a second embodiment of the invention. As shown in Figure 5, the method includes Step 201 to Step 206. The embodiment can be taken as a preferred mode of implementation of the embodiment shown in Figure 4.

Step S201: A tube temperature of an evaporator is detected within a first target time period and a room temperature and an evaporator tube temperature within a second target time period.

In the embodiment of the invention, the first target time period and the second target time period are consecutive time periods, and the second target time period is behind the first target time period. A time period of the first target time period can be preset, and preferably, the duration of the first target time period can be preset as 3 min. In the embodiment of the invention, specifically, the step in which the evaporator tube temperature is detected within the first target time period includes that: a first evaporator tube temperature is detected at a first time, a second temperature is detected of the evaporator tube at a second time, and a third temperature of the evaporator tube is detected at a third time, in which the first time, the second time and the third time can be three successive time points within the first period of target time, and the first moment, the second moment and the third moment are arranged on a time axis according to a time sequence. In the embodiment of the invention, specifically, the step in which the evaporator tube temperature is detected within the second target time period includes that: a fourth evaporator tube temperature is detected in a fourth time, and a fifth is detected temperature of the evaporator tube at a fifth moment, where the fourth moment and the fifth moment are successive time points within the second target time period, and the fifth moment is after the fourth moment.

Step S202: It is judged whether the temperature of the tube within the first target time period increases continuously and reaches a maximum value.

It is important to note that within the first target time period, when the first tube temperature, the second tube temperature and the third tube temperature increase sequentially and the three tube temperatures are successive values, a first judgment module 201 judges that the evaporator tube temperature within the first target time period increases continuously. Likewise, under a critical state, when the first tube temperature and the third tube temperature are smaller than the second tube temperature, it is considered that the tube temperature within the first target time period increases continuously and reaches the value maximum under critical state. It is important to note that the second tube temperature corresponding to the second moment is a maximum temperature within the first target time period under the critical state. If it is considered that the temperature of the evaporator tube within the first target time period is continuously increasing and reaches the maximum value, Step S203 is executed, and otherwise, Step S201 is executed.

Step S203: It is judged whether a temperature difference obtained by continuously increasing the temperature of the evaporator tube within the first target time period is greater than or equal to a preset temperature difference.

After judging that the temperature of the evaporator tube within the first target time period increases continuously and reaches the maximum value, it is judged whether the temperature difference obtained by the continuous increase in the temperature of the evaporator tube within the first time period target is greater than or equal to the preset temperature difference. For example, when the preset temperature difference is 15 GRAD C, and when the difference between a tube temperature at an end point of the first target time period and a tube temperature at a start point of the first target time period is greater than 15 GRAD C within the first target time period, the temperature difference obtained by the continuous increase of the evaporator tube temperature within the first target time period is considered to be greater than the preset temperature difference. When it is judged that the temperature difference obtained by the continuous increase in the temperature of the evaporator tube within the first target time period is greater than the preset temperature difference, Step S204 is executed, and otherwise, Step S201 runs.

It is important to note that Step S202 and Step S203 can be executed in reverse sequence.

Step S204: It is judged whether a difference between the room temperature and the temperature of the evaporator tube within the second target time period is less than a preset temperature difference limit value.

In carrying out the invention, if it is considered that the temperature difference obtained by the continuous increase in the temperature of the evaporator tube is greater than or equal to the preset temperature difference, it is judged whether the difference between the ambient temperature and the temperature of the evaporator tube within the second target time period is less than the preset temperature difference limit value, in which the preset temperature difference limit value can be 5 GRAD C. If the difference between the temperature and the temperature of the evaporator tube within the second target time period is less than the limit value of the preset temperature difference, Step S205 is executed, and if not, Step S201 is executed again. In the embodiment of the invention, when a fourth detection module detects the fourth temperature of the tube and a fifth detection module detects the fifth temperature of the tube, it can be calculate a temperature difference between the fifth tube temperature and the fourth tube temperature. Within the second target time period, when the fifth tube temperature is less than the fourth tube temperature, that is, when the temperature difference is less than 0 and the temperatures of the two tubes are successive values, the evaporator tube temperature within the second target time period drops continuously. If the difference between the ambient temperature and the evaporator tube temperature within the second target time period is judged to be less than the preset temperature difference limit value, and the evaporator tube temperature within the second period is judged target time drops continuously, Step S205 executes and Step S201 executes again.

Step S205: It is determined that the compressor is under overload protection.

If the difference between the ambient temperature and the evaporator tube temperature within the second target time period is judged to be less than the preset temperature difference limit value, it is determined that the compressor is under the overload protection. Otherwise, the compressor is considered not under the overload protection. If it is determined that the compressor is under the overload protection, Step S206 executes.

Step S206: If the compressor is under overload protection, the fluorine shortage protection is protected.

In carrying out the invention, the protection against fluoride shortage can be protected by taking the steps detailed below.

You get a preset overload protection time period. For example, the preset overload protection time period can be set as 60 min. After obtaining the preset overload protection time period, removing the first target time period and the second target time period from the preset overload protection time period to determine a third target time period, in which the first Target time period, the second target time period, and the third target time period are successive time periods, and the third target time period is behind the second target time period. After obtaining the third target time period, the protection against fluorine shortage is protected within the third target time period, or the protection against fluoride shortage is protected within a certain period of time that extends from the third target time period. For example, suppose the preset overload protection time period is set to 60 min and the durations of the first target time period and the second target time period are 3 min and 5 min, the third target time period are as follows. last 52 min of a given time. Therefore, the protection against fluoride shortage can be protected within the last 52 min of the set time or the protection against fluorine shortage can be protected between the last 52 min of the set time and the first 10 min of the set time. next hour.

Also, in the embodiment of the invention, before the fluorine shortage protection is protected within the third target time period, a fluorine shortage protection stop command sent to the compressor is obtained, in which the fluorine shortage protection stop command includes a first fluorine shortage protection stop command, a second fluorine shortage protection stop command, and a third fluorine shortage protection stop command. Specifically, when fluorine shortage protection data is detected for the first time, the main controller sends the first fluorine shortage protection stop command to the compressor; When the fluorine shortage protection data is detected a second time, the main controller sends the second fluorine shortage protection stop command to the compressor; and when the fluorine shortage protection data is detected for the third time, the main controller sends the third fluorine shortage protection stop command to the compressor. It is detected whether a time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period. When the time when the third fluorine shortage protection stop command is detected to be within the first target time period or the second target time period, the fluorine shortage is detected, and otherwise , the protection against fluoride shortage is not protected. When it is detected that the time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, the fluorine shortage protection is not protected. At that time, the fluorine shortage protection is determined to be the normal fluoride shortage protection, and a fluoride shortage protection alarm is issued.

From the above descriptions, it can be seen that by means of the invention, after judging that the temperature of the evaporator tube within the first target time period increases continuously and reaches the maximum value, it is considered that the temperature difference obtained by the Continuous rise in evaporator tube temperature within the first target time period is greater than or equal to the preset temperature difference and the difference between room temperature and tube is considered the evaporator temperature within the second target time period is less than the preset temperature difference limit value, the fluorine shortage protection is protected, and a false alarm for the shortage of fluorine, thus achieving the effect of avoiding the false fluorine shortage alarm when the compressor is under the overload protection.

It is important to note that the steps shown in the flowcharts in the drawings can be performed on a computer system that includes a set of computer-executable instructions. Also, although a logical sequence is shown in the flowcharts, the steps shown or described may be executed in a different sequence than the sequence here under certain conditions.

Obviously, those skilled in the art should understand that all the modules or all the steps of the invention can be carried out using a general calculation device, can be centralized in a single calculation device or can be distributed in a network composed of a plurality of calculation devices calculation. Optionally, they can be done using executable program codes of the calculation apparatuses. Thus, they can be stored in a storage apparatus and executed by the computing apparatuses, or they are manufactured in each IC module respectively, or a plurality of modules or stages therein are manufactured in a single IC module. Therefore, the invention is not limited to a combination of any specific hardware and software.

Claims (12)

1. A compressor overload protection control method, wherein the compressor overload protection control method is configured for overload protection of a dehumidifier and an air conditioner, and each of the dehumidifier and air conditioner. air comprises an evaporator and the compressor, the compressor overload protection control method comprising: detecting (S101) whether the compressor is in the on state or off state by detecting the temperature of an evaporator tube; judging (S102) that the compressor is under overload protection when the compressor is in the off state and judging that the compressor is not under overload protection when the compressor is in the on state; Y protect (S103) fluorine shortage protection if the compressor is under overload protection. The compressor overload protection control method according to claim 1, wherein detecting the state of the compressor comprises: detecting (S201) an evaporator tube temperature within a first target time period and a temperature and an evaporator tube temperature within a second target time period, with the first target time period and the second target time period being consecutive time periods, and the second target time period being after the first time period objective; Y judging whether the compressor is under the overload protection comprises: judging (S202) whether the tube temperature within the first target time period is continuously increasing and reaching a maximum value; after judging that the tube temperature within the first target time period is continuously increasing and reaches the maximum value, judge (S203) whether a temperature difference obtained by continuously increasing the tube temperature within the first target time period is greater than or equal to a preset temperature difference; After judging that the temperature difference obtained by the continuous increase in the tube temperature within the first target time period is greater than or equal to the preset temperature difference, judge (S204) whether a difference between the ambient temperature and the temperature of the tube within the second target time period is less than a preset temperature difference limit value; and if the difference between the ambient temperature and the tube temperature within the second target time period is considered to be less than the preset temperature difference limit value, determine (S205) that the compressor is under the overload protection. The compressor overload protection control method according to claim 2, wherein detecting the evaporator tube temperature within the first target time period comprises: detecting a first evaporator tube temperature at a first time , detect a second evaporator tube temperature at a second time, and detect a third evaporator tube temperature at a third time, with the first time, second time, and third time being successive time points within the first target time period , the second moment being after the first moment and the third moment being after the second moment; Y judging whether the tube temperature within the first target time period continuously increases and reaches the maximum value comprises: judging whether the evaporator tube temperature within the first target time period continuously increases and reaches the maximum value by judging a size relationship between the first tube temperature, the second tube temperature and the third tube temperature. The compressor overload protection control method according to claim 2, wherein detecting the evaporator tube temperature within the second target time period comprises: detecting a fourth evaporator tube temperature at a fourth time and detecting a fifth temperature of the evaporator tube at a fifth moment, the fourth moment and the fifth moment being successive time points within the second target time period, and the fifth moment being after the fourth moment; and judging whether the difference between the ambient temperature and the tube temperature within the second target time period is less than the preset temperature difference limit value comprises: calculating a temperature difference between the fifth tube temperature and the fourth temperature of the tube; and judging whether the tube temperature falls continuously within the second target time period by judging whether the temperature difference is less than 0. The compressor overload protection control method according to claim 2, wherein protecting the protection against fluorine shortage comprises: obtain a preset overload protection time period; remove the first target time period and the second target time period from the preset overload protection time period to determine a third target time period, the third target time period being after the second target time period and the third being target time period after the second target time period; Y protect protection against fluoride shortage within the third target time period. The compressor overload protection control method according to claim 5, wherein before the fluorine shortage protection is protected within the third target time period, protecting the fluorine shortage protection further includes: get a fluorine shortage protection stop command sent to the compressor, including the fluorine shortage protection stop command a first fluorine shortage protection stop command, a second shortage protection stop command of fluorine and a third stop command to protect against fluorine shortage; Y detect whether a time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, If it is detected that the time when the third fluorine shortage protection stop command is sent is not within the first target time period or the second target time period, the fluorine shortage protection is protected. 7. A compressor overload protection control apparatus, wherein the compressor overload protection control apparatus is configured for overload protection of a dehumidifier and an air conditioner, and each of the dehumidifier and air conditioner. air comprises an evaporator and the compressor, the compressor overload protection control apparatus comprising: a detection unit (10), configured to detect whether the compressor is in the on state or in the off state by detecting the temperature of the tube of an evaporator; a judgment unit (20), configured to judge that the compressor is under overload protection when the compressor is in the off state and judge that the compressor is not under overload protection when the compressor is in the on state; Y a protection unit (30), configured to protect the protection against fluorine shortage if the compressor is under overload protection. The compressor overload protection control apparatus according to claim 7, wherein the sensing unit (10) is further configured to detect an evaporator tube temperature within a first target time period and a ambient temperature and an evaporator tube temperature within a second target time period, with the first target time period and the second target time period being consecutive time periods, and the second target time period being after the first target period. target time; Y The judgment unit (20) comprises: a first judgment module (201), configured to judge whether the temperature of the tube within the first target time period is continuously increasing and reaching a maximum value; a second judgment module (202), configured to judge whether a temperature difference obtained by continuously increasing tube temperature within the first target time period is greater than or equal to a preset temperature difference after judging that the temperature tube within the first target time period continuously increases and reaches the maximum value; a third judgment module (203), configured to judge whether a difference between room temperature and tube temperature within the second target time period is less than a pre-set temperature difference limit value after the difference is judged of temperature obtained by the continuous increase of the temperature of the tube within the first the target period of time is greater than or equal to the pre-established temperature difference; and a first determination module (204), configured to judge that the compressor is under overload protection if the difference between ambient temperature and tube temperature within the second target time period is considered to be less than the limit value preset temperature difference. The compressor overload protection control apparatus according to claim 8, wherein the sensing unit (10) comprises: a first detection module, configured to detect a first evaporator tube temperature at first; a second detection module, configured to detect a second temperature of the evaporator tube in a second moment; Y a third detection module, configured to detect a third temperature of the evaporator tube at a third time, being the first moment, the second moment and the third moment successive time points within the first objective period of time, the second moment being after the first moment, the third moment being after the second moment, and also configuring the first evaluation module to judge whether the evaporator tube temperature within the first target time period continuously increases and reaches the maximum value by judging a size relationship between the first tube temperature, the second tube temperature, and the third tube temperature. The compressor overload protection control apparatus according to claim 8, wherein The detection unit (10) further comprises: a fourth detection module, configured to detect a fourth temperature of the evaporator tube in a fourth time; and a fifth detection module, configured to detect a fifth temperature of the evaporator tube at a fifth moment, the fourth moment and the fifth moment being successive time points within the second target time period, and the fifth moment being after the fourth moment; Y the second judgment module comprises: a calculation sub-module, configured to calculate a temperature difference between the fifth tube temperature and the fourth tube temperature; and a judgment sub-module, configured to judge whether the tube temperature continuously falls within the second target time period by judging whether the temperature difference is less than 0. The compressor overload protection control apparatus according to claim 8, wherein the protection unit (30) comprises: a first obtaining module, configured to obtain a preset overload protection time period; a second determination module, configured to remove the first target time period and the second target time period from the preset overload protection time period to determine a third target time period, the third target time period being successive to the second target time period and being the third target time period after the second target time period; Y a protection module, configured to protect protection against fluorine shortage within the third target time period. The compressor overload protection control apparatus according to claim 11, wherein the protection unit (30) further comprises: a second obtaining module, configured to obtain a fluorine shortage protection stop command sent to the compressor before the fluorine shortage protection is protected within the third target time period, including the protection stop command against fluorine shortage a first fluorine shortage protection stop command, a second fluorine shortage protection stop command and a third fluorine shortage protection stop command; and a sixth detection module, configured to detect whether a time when the third fluorine shortage protection stop command is sent is within the first target time period or the second target time period, the protection unit being further configured to protect the protection against fluorine shortage when it is detected that the time at which the third fluorine shortage protection stop command is sent is not within the first target time period or the second target time period.